Amylase synthesis and stability in crested wheatgrass seeds at low water potentials

Drying of seeds of Agropyron desertorum (Fisch. ex Link) Schult. did not result in breakdown of α-amylase nor impair the ability of seeds to resume its synthesis when moistened again. β-Amylase activity did not change during 5 days of germination at a water potential of 0 atmosphere nor during 40 days of incubation at −40 atmospheres. Seeds synthesized α-amylase at 0, −20, and −40 atmospheres, but not at −60 atmospheres. At 0 and −20 atmospheres, the log of α-amylase activity was linearly related to hastening of germination. But at −40 atmospheres, seeds synthesized α-amylase during a time when there was little hastening of germination. Thus, it appears that other biochemical reactions are less drought-tolerant than synthesis of α-amylase. It is concluded that inhibition of α-amylase synthesis is not a controlling factor in the germination of these seeds at low water potentials.     

Enzymic Mechanism of Starch Breakdown in Germinating Rice Seeds: 9. DE NOVO SYNTHESIS OF beta-AMYLASE

Germinating rice seeds were fed with [³⁵S]methionine and the incorporation of ³⁵S into β-amylase demonstrated by quantitative immunoprecipitation using rabbit anti-β-amylase immunoglobulin G fraction. Separation of the antigen-antibody complex by Na-dodecylsulfate gel electrophoresis and subsequent radioautography clearly showed the radioactive labeling of the β-amylase molecule. The specific radioactivity of β-amylase derived from scutellum by immunoprecipitation was significantly greater than that of the endosperm. The results strongly indicate that at the onset of germination of rice seeds β-amylase is synthesized de novo in the scutellum and that in later stages there occurs activation of an inactive, latent form of the enzyme associated with starch granules in the endosperm. In later stages of germination this activated form of the enzyme becomes dominant.     

The pattern and control of isoprenoid quinone and tocopherol metabolism in the germinating grain of wheat (Triticum vulgare)

1. The syntheses of ubiquinone-9 and plastoquinone-9 were used as parameters respectively of mitochondrial and proplastid development in the germinating wheat grain. 2. The changes in the amounts of the tocopherols were also studied and the possible biological significance of these changes is discussed. During germination, the dimethyl tocopherols of the resting grain are probably not utilized for the synthesis of α-tocopherol. 3. It was demonstrated that ubiquinone synthesis, and hence probably mitochondrial development, in the aleurone cells during germination, is independent of control by gibberellic acid from the embryo. 4. The influence of light on the syntheses of the isoprenoid quinones in the etiolated wheat shoot was investigated. In particular, illumination did not stimulate the synthesis of either α-tocopherol or α-tocopherolquinone.     

Immunochemical Studies on Arachis hypogaea Proteins With Particular Reference to the Reserve Proteins. II. Protein Modification During Germination

α-Conarachin and α-arachin are metabolized differently during germination. The amount of α-conarachin decreases without the appearance of antigenic intermediary compounds. α-Arachin retains its original antigenic structure and becomes more anodic during germination, but a number of intermediary proteins, differing widely in electrophoretic mobility, form up to 14 days germination. The electrophoretic shift of α-arachin, detectable after 1 day of germination, might be caused by progressive deamidation of glutamine and asparagine. Decreases in amide content of protein extracted after germination support the hypothesis and suggest that α-arachin provides the first source of ammonia to the new seedling.     

beta-Amylases in Cereals : A Study of the Maize beta-Amylase System

β-Amylase of maize (Zea mays L.) caryopses was studied during development and germination by means of enzymic, electrophoretic, and immunochemical techniques. β-Amylase activity increased during caryopsis development to a maximum value at the beginning of the water content plateau (at this stage the enzyme was located primarily within the pericarp) and then decreased. Almost no β-amylase (activity or antigen) was found in either free or bound forms in the mature maize caryopsis. The activity increased again during seedling growth and reached much higher values. Both the aleurone layer (to a major extent) and the scutellum produced and secreted β-amylase during germination, the secretion being stimulated by Ca²⁺. No posttranslational modification of the enzyme was detected during germination. The molecular specific activity of the enzyme remained unchanged during the observed periods, indicating that the regulation of the activity is based essentially on protein turnover. The enzyme from developing and germinating caryopses was found to be identical in terms of antigenicity, isoelectric point, and molecular mass to the β-amylases extracted from the roots and the leaves of the maize seedling. The maize β-amylase resembles in all respects the ubiquitous β-amylase described for rye and wheat, whereas the major β-amylase of those cereals appears to be lacking in the maize caryopsis.     

Independent Regulatory Aspects and Posttranslational Modifications of Two beta-Amylases of Rye : Use of a Mutant Inbred Line

We have examined the occurrence/disappearance, tissue location, and posttranslational modification of β-amylase proteins in rye (Secale cereale L.) kernels at three physiological stages (development, maturity, germination) with a normal inbred line and a mutant line exhibiting a high but incomplete β-amylase deficiency. This deficiency corresponds to a lack of accumulation of β-amylase activity in the endosperm and does not affect the level of activity in the outer pericarp and green tissues as compared to the normal line. Two antigenically related but distinct β-amylases (I and II) were detected in the normal line (II being the major constituent) and only one (I) in the mutant line. I and II display very similar electrophoretic polymorphism. In both lines, I appears to be ubiquitous, although it disappears from the outer pericarp during ripening. Antigen II was present only in the normal line and appears to be specific for the endosperm and perhaps for the maternal green tissues of the seed. Posttranslational modifications occurring during germination, which are mimicked by the action of papain, affect II but not I. The two groups of β-amylases are discussed in relation to recent reports indicating the presence of two types of β-amylase with different functions and gene loci in barley and wheat.     

Translational Control in Plasmodium and Toxoplasma Parasites

The life cycles of apicomplexan parasites such as Plasmodium spp. and Toxoplasma gondii are complex, consisting of proliferative and latent stages within multiple hosts. Dramatic transformations take place during the cycles, and they demand precise control of gene expression at all levels, including translation. This review focuses on the mechanisms that regulate translational control in Plasmodium and Toxoplasma, with a particular emphasis on the phosphorylation of the α subunit of eukaryotic translation initiation factor 2 (eIF2α). Phosphorylation of eIF2α (eIF2α∼P) is a conserved mechanism that eukaryotic cells use to repress global protein synthesis while enhancing gene-specific translation of a subset of mRNAs. Elevated levels of eIF2α∼P have been observed during latent stages in both Toxoplasma and Plasmodium, indicating that translational control plays a role in maintaining dormancy. Parasite-specific eIF2α kinases and phosphatases are also required for proper developmental transitions and adaptation to cellular stresses encountered during the life cycle. Identification of small-molecule inhibitors of apicomplexan eIF2α kinases may selectively interfere with parasite translational control and lead to the development of new therapies to treat malaria and toxoplasmosis.     

Secretion of alpha-amylase by the aleurone layer and the scutellum of germinating barley grain

α-Amylase activities in extracts of different parts of barley grain (Hordeum vulgare L. cv Himalaya) were low after 1 day of germination at 20°C, but they began to increase afterwards. In the scutellum and the aleurone layer, the increases were small, but in the starchy endosperm a great increase took place between days 1 and 6.

When the aleurone layers were separated from germinating whole grains and incubated in 10 millimolar CaCl₂, the α-amylase activity in the medium increased linearly for about 30 to 60 minutes, indicating secretion. The activity inside the aleurone layer decreased only slightly during the incubation, indicating that secretion of α-amylase was accompanied by synthesis. The rates of secretion in vitro by the aleurone layers separated at different stages of germination corresponded rather well to the rate of accumulation of α-amylase activity in the starchy endosperm in a whole grain.

Scutella separated after 1 day of germination released small amounts of α-amylase activity into 10 millimolar CaCl₂. This release was linear for at least 1 hour and did not occur at 0°C; it is therefore likely to be due to secretion. At later stages of germination, the secretion by the scutella was slower than at day 1 and the total secretion accounted for only 5 to 10% of the increase of α-amylase activity in the starchy endosperm in a whole grain.

Since the times from the separation of the parts of the grain to the beginning of the secretion assay (10-40 minutes) as well as the duration of the assay itself (20-60 minutes) were short, the rates of secretion by the separated grain parts are likely to represent those in an intact grain. The results indicate therefore that at least in the conditions used the bulk of the total α-amylase in the starchy endosperm is secreted by the aleurone layer, the contribution by the scutellum being only 5 to 10% of the total activity.

     

Conversion of Exogenous Cholesterol into Glycoalkaloids in Potato Shoots,Using Two Methods for Sterol Solubilisation

Steroidal glycoalkaloids (SGA) are toxic secondary metabolites naturally occurring in the potato, as well as in certain other Solanaceous plant species, such as tomato, eggplant and pepper. To investigate the steroidal origin of SGA biosynthesis, cut potato shoots were fed cholesterol labelled with deuterium (D) in the sterol ring structure (D₅- or D₆-labelled), or side chain (D₇-labelled), and analysed after three or five weeks. The labelled cholesterol and presence of D-labelled SGA were analysed by GC-MS and LC-MS/MS, respectively. When feeding D-labelled cholesterol solubilised in Tween-80, labelled cholesterol in free form became present in both leaves and stems, although the major part was recovered as steryl esters. Minor amounts of D-labelled SGA (α-solanine and α-chaconine) were identified in cholesterol-treated shoots, but not in blank controls, or in shoots fed D₆-27-hydroxycholesterol. Solubilising the labelled cholesterol in methyl-β-cyclodextrin instead of Tween-80 increased the levels of labelled SGA up to 100-fold, and about 1 mole% of the labelled cholesterol was recovered as labelled SGA in potato leaves. Both side chain and ring structure D labels were retained in SGA, showing that the entire cholesterol molecule is converted to SGA. However, feeding side chain D₇-labelled cholesterol resulted in D₅-labelled SGA, indicating that two hydrogen atoms were released during formation of the SGA nitrogen-containing ring system. Feeding with D₇-sitosterol did not produce any labelled SGA, indicating that cholesterol is a specific SGA precursor. In conclusion, we have demonstrated a superior performance of methyl-β-cyclodextrin for delivery of cholesterol in plant tissue feeding experiments, and given firm evidence for cholesterol as a specific sterol precursor of SGA in potato.     

Effect of gibberellic Acid and actinomycin d on the formation and distribution of rough endoplasmic reticulum in barley aleurone cells

Analysis of structural changes in barley aleurone cells during germination or following incubation of isolated layers in gibberellic acid with or without actinomycin D revealed extensive development of rough endoplasmic reticulum. Following the assembly of stacked rough endoplasmic reticulum, vesiculation occurred mainly in basal regions of the cell, resulting in a polar distribution of rough endoplasmic reticulum vesicles. It is postulated that these vesicles are involved in protein secretion, because smooth vesicles, derived from the rough endoplasmic reticulum, apparently become appressed to the plasma membrane. The increased α-amylase in the ambient medium and in cell homogenates correlated directly with formation and subsequent vesiculation of the rough endoplasmic reticulum. Furthermore, when cells were treated with actinomycin D and gibberellic acid, α-amylase synthesis was inhibited by 45% and secretion by 63%. These cells were characterized cytologically by large areas of disarrayed segments of fragmented rough endoplasmic reticulum, corresponding to a high intracellular level of α-amylase. In addition, small lipid bodies common to the segmented regions of rough endoplasmic reticulum were surrounded by fine fibrous material, short segments of rough endoplasmic reticulum, and free ribosomes, suggesting that actinomycin D had interfered with development and organization of rough endoplasmic reticulum.     

Site-1 protease-activated formation of lysosomal targeting motifs is independent of the lipogenic transcription control

Site-1 protease (S1P) cleaves membrane-bound lipogenic sterol regulatory element-binding proteins (SREBPs) and the α/β-subunit precursor protein of the N-acetylglucosamine-1-phosphotransferase forming mannose 6-phosphate (M6P) targeting markers on lysosomal enzymes. The translocation of SREBPs from the endoplasmic reticulum (ER) to the Golgi-resident S1P depends on the intracellular sterol content, but it is unknown whether the ER exit of the α/β-subunit precursor is regulated. Here, we investigated the effect of cholesterol depletion (atorvastatin treatment) and elevation (LDL overload) on ER-Golgi transport, S1P-mediated cleavage of the α/β-subunit precursor, and the subsequent targeting of lysosomal enzymes along the biosynthetic and endocytic pathway to lysosomes. The data showed that the proteolytic cleavage of the α/β-subunit precursor into mature and enzymatically active subunits does not depend on the cholesterol content. In either treatment, lysosomal enzymes are normally decorated with M6P residues, allowing the proper sorting to lysosomes. In addition, we found that, in fibroblasts of mucolipidosis type II mice and Niemann-Pick type C patients characterized by aberrant cholesterol accumulation, the proteolytic cleavage of the α/β-subunit precursor was not impaired. We conclude that S1P substrate-dependent regulatory mechanisms for lipid synthesis and biogenesis of lysosomes are different.     

Urinary excretion of C-20-reduction products of corticosterone

1. A 200 mg. portion of corticosterone was ingested by a healthy man and the urine collected. Part of the urine was treated with the gastric juice of Helix pomatia and extracted with ethyl acetate, and the extract fractionated with Girard T. Paper-chromatographic separation of the non-ketonic fraction in the Bush (1952) system B₅ revealed the presence of two unknown polar components. 2. The unknown compounds did not possess a reducing (blue tetrazolium) or a reducible (potassium borohydride) grouping. Both contained a terminal α-glycollic fragment as shown by the formation of formaldehyde, and of a non-volatile aldehyde on oxidation with sodium bismuthate. 3. Unknown compound (I) had paper-chromatographic mobilities identical with those of 5β-pregnane-3α,11β,20β,21-tetraol. The oxidation product of compound (I) had a retention time (gas–liquid chromatography) on an SE30 column identical with that of 3α,11β-dihydroxy-21-nor-5β-pregnan-20-al. The retention times of various derivatives agreed with those produced in an identical manner on the standard, and accordingly compound (I) is formulated as 5β-pregnane-3α,11β,20ξ,21-tetraol. 4. Unknown compound (II) had a higher R_F than compound (I), and its oxidation product had a longer retention time than that of compound (I). From the group effects observed in paper and gas–liquid chromatography, compound (II) is tentatively formulated as 5α-pregnane-3α,11β,20ξ,21-tetraol. The 5α/5β ratio found was about 2·0.     

The metabolism of the fluorescent probe cholesta-5,7,9(11)-trien-3β-ol by rat liver

The chemical synthesis and metabolism of [3α-³H]cholesta-5,7,9(11)-trien-3β-ol is described. This radioactive fluorescent sterol probe cannot be rearranged or converted to cholesterol by rat liver but is readily esterified.     

Changes in Sterol Composition during Greening of Etiolated Barley Shoots

The following sterols were identified in barley shoots: stigmasterol, β-sitosterol, campesterol, and cholesterol. The total sterol content of green and etiolated tissue was 2.84 and 3.20 milligrams per gram dry weight, respectively. The free sterols accounted for most of the difference in total sterol content. The sterol ester, sterol glycoside, and acylated sterol glycoside contents of green and etiolated barley shoots were essentially the same. Etiolated tissue had twice as much total β-sitosterol as stigmasterol, while green tissue had equal amounts of these two sterols. The campesterol and cholesterol content was the same in green and etiolated tissue. This same sterol composition pattern held true for the free, glycosidic, and acylated glycosidic sterols; however, the sterol ester fraction had a completely different composition pattern. The esterified stigmasterol content was quite low in green and etiolated tissue, and campesterol was the second largest esterfied sterol component in etiolated tissue. Etiolated barley seedlings exposed to light had a shift in the ratio of free stigmasterol to β-sitosterol in favor of stigmasterol; however, no correlation was observed between chlorophyll synthesis and shift in sterol composition.     

A Function for Phosphatidylinositol 3-Kinase β (p85α-p110β) in Fibroblasts during Mitogenesis: Requirement for Insulin- and Lysophosphatidic Acid-Mediated Signal Transduction

We have previously shown that phosphatidylinositol 3-kinase α (PI 3-Kα) (p85α-p110α) is required for DNA synthesis induced by various growth factors (S. Roche, M. Koegl, and S. A. Courtneidge, Proc. Natl. Acad. Sci. USA 91:9185–9189, 1994) in fibroblasts. In the present study, we have investigated the function of PI 3-Kβ (p85α-p110β) during mitogenesis. By using antibodies specific to p110β we showed that PI 3-Kβ is expressed in NIH 3T3 cells. PI 3-Kβ and PI 3-Kα have common features: PI 3-Kβ is tightly associated with a protein serine kinase that phosphorylates p85α, it interacts with the Src-middle T antigen complex and the activated platelet-derived growth factor (PDGF) receptor in fibroblasts in vivo, and it becomes tyrosine phosphorylated after PDGF stimulation. PI 3-Kβ was also activated in Swiss 3T3 and Cos7 cells stimulated with lysophosphatidic acid (LPA), a mitogen that interacts with a heterotrimeric G protein-coupled receptor. In contrast PI 3-Kα was activated to a lesser extent in these cells. Microinjection of neutralizing antibodies specific for p110β into quiescent fibroblasts inhibited DNA synthesis induced by both insulin and LPA but poorly affected PDGF receptor signaling. Therefore, PI 3-Kβ plays an important role in transmitting the mitogenic response induced by some, but not all, growth factors. Finally, we show that while oncogenic V12Ras interacts with type I PI 3-Ks, it could induce DNA synthesis in the absence of active PI 3-Kα and PI 3-Kβ, suggesting that Ras uses other effectors for DNA synthesis.     

Beta-Catenin and Plakoglobin Expression during Zebrafish Tooth Development and Replacement

We analyzed the protein distribution of two cadherin-associated molecules, plakoglobin and β-catenin, during the different stages of tooth development and tooth replacement in zebrafish. Plakoglobin was detected at the plasma membrane already at the onset of tooth development in the epithelial cells of the tooth. This pattern remained unaltered during further tooth development. The mesenchymal cells only showed plakoglobin from cytodifferentiation onwards. Plakoglobin 1a morpholino-injected embryos showed normal tooth development with proper initiation and differentiation. Although plakoglobin is clearly present during normal odontogenesis, the loss of plakoglobin 1a does not influence tooth development. β-catenin was found at the cell borders of all cells of the successional lamina but also in the nuclei of surrounding mesenchymal cells. Only membranous, not nuclear, β-catenin, was found during morphogenesis stage. However, during cytodifferentiation stage, both nuclear and membrane-bound β-catenin was detected in the layers of the enamel organ as well as in the differentiating odontoblasts. Nuclear β-catenin is an indication of an activated Wnt pathway, therefore suggesting a possible role for Wnt signalling during zebrafish tooth development and replacement.     

Interaction of Chloroplasts with Inhibitors: Location of Carotenoid Synthesis and Inhibition during Chloroplast Development

The inhibitor SAN 6706 [4-chloro-5-(dimethylamino)-2-(α,α,α,-trifluoro- m-tolyl-3(2H)-pyridazinone] has been used to study the synthesis of carotenes and xanthophylls during the conversion of etioplasts to chloroplasts in developing barley (Hordeum vulgare) shoots. SAN 6706 inhibits carotenoid synthesis and causes an accumulation of phytoene, but it is also a potent inhibitor of chloroplast electron transport. When developing barley is treated with SAN 6706, carotenoid synthesis is inhibited but total photosynthesis is unaffected. The ability of SAN 6706 to inhibit carotenoid synthesis becomes progressively less if etiolated shoots are illuminated for increasing lengths of time before treatment. During the greening of treated barley shoots only light-induced β-carotene synthesis is immediately inhibited; xanthophyll synthesis is not affected until after about 8 hours. The hypothesis that SAN 6706 cannot enter the chloroplast but inhibits carotenoid synthesis from the cytoplasm is discussed, and the question as to whether there are not two separate groups of enzymes for the synthesis of carotenes and xanthophylls is considered.     

The Steric Gate of DNA Polymerase ι Regulates Ribonucleotide Incorporation and Deoxyribonucleotide Fidelity

Accurate DNA synthesis in vivo depends on the ability of DNA polymerases to select dNTPs from a nucleotide pool dominated by NTPs. High fidelity replicative polymerases have evolved to efficiently exclude NTPs while copying long stretches of undamaged DNA. However, to bypass DNA damage, cells utilize specialized low fidelity polymerases to perform translesion DNA synthesis (TLS). Of interest is human DNA polymerase ι (pol ι), which has been implicated in TLS of oxidative and UV-induced lesions. Here, we evaluate the ability of pol ι to incorporate NTPs during DNA synthesis. pol ι incorporates and extends NTPs opposite damaged and undamaged template bases in a template-specific manner. The Y39A “steric gate” pol ι mutant is considerably more active in the presence of Mn²⁺ compared with Mg²⁺ and exhibits a marked increase in NTP incorporation and extension, and surprisingly, it also exhibits increased dNTP base selectivity. Our results indicate that a single residue in pol ι is able to discriminate between NTPs and dNTPs during DNA synthesis. Because wild-type pol ι incorporates NTPs in a template-specific manner, certain DNA sequences may be “at risk” for elevated mutagenesis during pol ι-dependent TLS. Molecular modeling indicates that the constricted active site of wild-type pol ι becomes more spacious in the Y39A variant. Therefore, the Y39A substitution not only permits incorporation of ribonucleotides but also causes the enzyme to favor faithful Watson-Crick base pairing over mutagenic configurations.